arccoza/callable-object-constructor.js

## callable-object-constructor.js
// This is my approach to creating callable objects
// that correctly reference their object members,
// without messing with prototypes.

// A Class that extends Function so we can create
// objects that also behave like functions, i.e. callable objects.
class ExFunc extends Function {
  constructor() {
    // Here we create a dynamic function with `super`,
    // which calls the constructor of the parent class, `Function`.
    // The dynamic function simply passes any calls onto
    // an overridable object method which I named `__call__`.
    // But there is a problem, the dynamic function created from
    // the strings sent to `super` doesn't have any reference to `this`;
    // our new object. There are in fact two `this` objects; the outer
    // one being created by our class inside `constructor` and an inner
    // one created by `super` for the dynamic function.
    // So the reference to this in the text: `return this.__call__(...args)`
    // does not refer to `this` inside `constructor`.
    // So attempting:
    // `obj = new ExFunc();`
    // `obj();`
    // Will throw an Error because __call__ doesn't exist to the dynamic function.
    super('...args', 'return this.__call__(...args)');

    // `bind` is the simple remedy to this reference problem.
    // Because the outer `this` is also a function we can call `bind` on it
    // and set a new inner `this` reference. So we bind the inner `this`
    // of our dynamic function to point to the outer `this` of our object.
    // Now our dynamic function can access all the members of our new object.
    // So attempting:
    // `obj = new Exfunc();`
    // `obj();`
    // Will work.
    // We return the freshly bound `this`.
    return this.bind(this);
  }

  // An example property to demonstrate member access.
  get venture() {
    return 'Hank';
  }

  // Override this method in subclasses of ExFunc to take whatever arguments
  // you want and perform whatever logic you like. It will be called whenever
  // you use the obj as a function.
  __call__(a, b, c) {
    return [this.venture, a, b, c];
  }
}

// A subclass of ExFunc with an overridden __call__ method.
class DaFunc extends ExFunc {
  get venture() {
    return 'Dean';
  }

  __call__(ans) {
    return [this.venture, ans];
  }
}

// Create objects from ExFunc and its subclass.
var callable1 = new ExFunc();
var callable2 = new DaFunc();

// Inheritance is correctly maintained.
console.log('\nInheritance maintained:');
console.log(callable2 instanceof Function);  // true
console.log(callable2 instanceof ExFunc);  // true
console.log(callable2 instanceof DaFunc);  // true

// Test ExFunc and its subclass objects by calling them like functions.
console.log('\nCallable objects:');
console.log( callable1(1, 2, 3) );  // [ 'Hank', 1, 2, 3 ]
console.log( callable2(42) );  // [ 'Dean', 42 ]
	// This is my approach to creating callable objects
	// that correctly reference their object members,
	// without messing with prototypes.

	// A Class that extends Function so we can create
	// objects that also behave like functions, i.e. callable objects.
	class ExFunc extends Function {
	constructor() {
	// Here we create a dynamic function with `super`,
	// which calls the constructor of the parent class, `Function`.
	// The dynamic function simply passes any calls onto
	// an overridable object method which I named `__call__`.
	// But there is a problem, the dynamic function created from
	// the strings sent to `super` doesn't have any reference to `this`;
	// our new object. There are in fact two `this` objects; the outer
	// one being created by our class inside `constructor` and an inner
	// one created by `super` for the dynamic function.
	// So the reference to this in the text: `return this.__call__(...args)`
	// does not refer to `this` inside `constructor`.
	// So attempting:
	// `obj = new ExFunc();`
	// `obj();`
	// Will throw an Error because __call__ doesn't exist to the dynamic function.
	super('...args', 'return this.__call__(...args)');

	// `bind` is the simple remedy to this reference problem.
	// Because the outer `this` is also a function we can call `bind` on it
	// and set a new inner `this` reference. So we bind the inner `this`
	// of our dynamic function to point to the outer `this` of our object.
	// Now our dynamic function can access all the members of our new object.
	// So attempting:
	// `obj = new Exfunc();`
	// `obj();`
	// Will work.
	// We return the freshly bound `this`.
	return this.bind(this);
	}

	// An example property to demonstrate member access.
	get venture() {
	return 'Hank';
	}

	// Override this method in subclasses of ExFunc to take whatever arguments
	// you want and perform whatever logic you like. It will be called whenever
	// you use the obj as a function.
	__call__(a, b, c) {
	return [this.venture, a, b, c];
	}
	}

	// A subclass of ExFunc with an overridden __call__ method.
	class DaFunc extends ExFunc {
	get venture() {
	return 'Dean';
	}

	__call__(ans) {
	return [this.venture, ans];
	}
	}

	// Create objects from ExFunc and its subclass.
	var callable1 = new ExFunc();
	var callable2 = new DaFunc();

	// Inheritance is correctly maintained.
	console.log('\nInheritance maintained:');
	console.log(callable2 instanceof Function); // true
	console.log(callable2 instanceof ExFunc); // true
	console.log(callable2 instanceof DaFunc); // true

	// Test ExFunc and its subclass objects by calling them like functions.
	console.log('\nCallable objects:');
	console.log( callable1(1, 2, 3) ); // [ 'Hank', 1, 2, 3 ]
	console.log( callable2(42) ); // [ 'Dean', 42 ]